KR20240155484A - Heat exchanger - Google Patents

Abstract

The present invention relates to a heat exchanger having an inner fin formed by folding in a corrugated shape with repeated hills and valleys inside a tube, wherein the inner fin includes a plurality of unit passages in which the hills and valleys are arranged in the width direction and each extends in the length direction, and the internal space of the tube is partitioned by the hills and valleys of the inner fin, and at least some of the plurality of unit passages are connected to each other in the width direction, so that a heat exchange medium can flow not only in the length direction of the tube and the inner fin but also in the width direction, thereby improving heat exchange performance.

Description

Heat exchanger {Heat exchanger}

The present invention relates to an inner fin for a heat exchanger, which is provided inside a tube through which a heat exchange medium flows in a heat exchanger to improve heat exchange efficiency, and to a heat exchanger including the inner fin.

A heat exchanger is a device that absorbs heat from one environment and releases heat to the other environment between two environments with a temperature difference. When it absorbs indoor heat and releases it to the outside, it operates as a cooling system, and when it absorbs outdoor heat and releases it to the inside, it operates as a heating system.

Fig. 1 is an assembly perspective view showing a conventional heat exchanger, and Fig. 2 is a cross-sectional view showing a tube and inner fin for a conventional heat exchanger.

A conventional heat exchanger comprises a pair of header tanks (10, 20) that form a space in which a heat exchange medium is stored and flows; a plurality of tubes (30) that are connected to the pair of header tanks (10, 20) to form a passage through which a heat exchange medium flows; and an outer fin (40) that is interposed and joined between the plurality of tubes (30). In addition, an inner fin (50) may be provided inside the tube (30) to improve heat exchange performance, and the inner fin (50) is inserted into the inside of the tube (30) and joined to the tube (30) by brazing, etc. In addition, the inner fin (50) is formed in a folded shape in the width direction.

However, the internal space of the tube into which the inner fin is inserted is configured so that a heat exchange medium flows along the longitudinal direction of the tube, and the mountain and valley portions of the inner fin are in contact with and joined to the inner surface of the tube.

Therefore, since the heat exchange medium cannot flow in the width direction of the tube and inner fin, heat exchange by width-wise convection of the heat exchange medium is limited, and accordingly, there is a limit to improving the heat exchange performance of the heat exchanger.

KR 10-2371382 B1 (2022.03.02)

The present invention has been made to solve the problems described above, and an object of the present invention is to provide an inner fin for a heat exchanger and a heat exchanger including the same, in which the shape of an inner fin provided inside a tube for a heat exchanger is improved so that the mountain and valley portions of the inner fin form an area where they come into contact with the inner surface of the tube and an area where they are not in contact, thereby allowing a heat exchange medium to flow not only in the longitudinal direction of the tube and inner fin but also in the width direction, thereby improving heat exchange performance.

In order to achieve the above-described purpose, the heat exchanger of the present invention comprises an inner fin formed by folding in a corrugated shape with repeated hills and valleys inside a tube, wherein the inner fin includes a plurality of unit channels in which the hills and valleys are arranged in the width direction and each extend in the length direction, and the internal space of the tube is partitioned by the hills and valleys of the inner fin, and at least some of the plurality of unit channels can be communicated with each other in the width direction.

In addition, at least one of the mountains or valleys may have an area formed that is relatively lower in height than the height of the mountains or valleys of the remaining portion, and the area with the relatively lower height of the mountains or valleys may be formed in a portion in the longitudinal direction, and the mountains and valleys may be in contact with the inner surface of the tube, and the area with the relatively lower height of the mountains or valleys may be spaced apart from the inner surface of the tube.

In addition, a concave height reduction portion is formed on at least one of the mountains or valleys, and the height reduction portion may be an area where the height of the mountain or valley is relatively low.

Additionally, a plurality of height reduction portions are formed on one mountain or valley, and the plurality of height reduction portions can be arranged to be spaced apart from each other in the longitudinal direction.

Additionally, the height reduction portion may be formed alternately in mountains or valleys along the width direction.

In addition, when a plurality of height decreasing portions alternately formed on mountains or valleys along the width direction are referred to as height decreasing portion groups, the height decreasing portion groups are formed in plurality and arranged to be spaced apart from each other in the length direction, and the plurality of height decreasing portion groups can be alternately formed on mountains and valleys along the length direction.

In addition, if among the plurality of height reduction part groups, a height reduction part group in which a height reduction part is formed in a mountain is referred to as a first height reduction part group, and if among the plurality of height reduction part groups, a height reduction part group in which a height reduction part is formed in a valley is referred to as a second height reduction part group, the first height reduction part groups may be formed in plural, and the plurality of first height reduction part groups may be arranged to be misaligned along the longitudinal direction, and the plurality of second height reduction part groups may be formed in plural, and the plurality of second height reduction part groups may be arranged to be misaligned along the longitudinal direction.

Additionally, the height reduction portion may be formed continuously in a mountain or valley along the width direction.

Additionally, the bottom surface and the sides on both sides in the longitudinal direction of the height reducing portion may be blocked.

In addition, the side surfaces of the height reducing portion connected to both sides in the longitudinal direction of the bottom surface of the height reducing portion may be connected at an acute angle to the surface forming the top of the mountain or valley on which the height reducing portion is formed.

Additionally, an opening may be formed on the longitudinal side adjacent to the height reduction portion.

In addition, the tubes may further include a pair of header tanks, which are provided in multiple numbers and arranged spaced apart from each other and in which the multiple tubes are connected; and an outer fin interposed between the multiple tubes.

The heat exchanger of the present invention has an advantage in that heat exchange performance can be improved because the heat exchange medium flows not only in the longitudinal direction of the tube and inner fin but also in the width direction.

In addition, there is an advantage in that the tube is firmly supported by the inner fin in the area where the peaks and valleys of the inner fin come into contact with the inner surface of the tube, and also in that the heat exchange medium can flow in the width direction in the area where the peaks and valleys of the inner fin are separated from the inner surface of the tube.

Figure 1 is an assembly perspective drawing showing a conventional heat exchanger.
Fig. 2 is a cross-sectional view showing a tube and inner fin for a conventional heat exchanger.
Figures 3 to 5 are perspective views showing tubes and inner fins of a heat exchanger according to the first embodiment of the present invention.
Figure 6 is a cross-sectional view at each location in Figure 4.
FIG. 7 is a side view showing the tubes and inner fins of a heat exchanger according to the first embodiment of the present invention.
FIG. 8 and FIG. 9 are perspective views showing tubes and inner fins of a heat exchanger according to a second embodiment of the present invention.
Figure 10 is a cross-sectional view at each location of Figure 9.
FIG. 11 is a cross-sectional view showing various embodiments of a height reducing portion in an inner fin of a heat exchanger according to a second embodiment of the present invention.
Fig. 12 is a front view showing the detailed shape of a height reduction portion of an inner fin of a heat exchanger according to a second embodiment of the present invention.
Figure 13 is an assembly perspective view showing the heat exchanger of the present invention.

Hereinafter, the heat exchanger of the present invention having the configuration described above will be described in detail with reference to the attached drawings.

FIGS. 3 to 5 are perspective views showing tubes and inner fins of a heat exchanger according to a first embodiment of the present invention, FIG. 6 is a cross-sectional view at each location of FIG. 4, and FIG. 7 is a side view showing tubes and inner fins of a heat exchanger according to a first embodiment of the present invention.

As described above, the inner fin (100) of the heat exchanger according to the first embodiment of the present invention may be provided inside a tube (200) through which a heat exchange medium flows, and the inner fin (100) may be joined to the tube (200) by brazing or the like. The inner fin (100) may be formed by bending in a corrugated shape with alternating peaks (110) and valleys (120) in the width direction. In addition, a plurality of peaks (110) and a plurality of valleys (120) may be formed to extend in a continuous shape along the length direction. Thus, the internal space of the tube (200) may be partitioned by the peaks (110) and valleys (120) of the inner fin (100), and a plurality of unit paths through which a heat exchange medium may flow may be formed. In addition, the drawing shows that the top of the mountain (110) and the top of the valley (120) are flat and the part connecting the mountain (110) and the valley (120) are inclined, but the top of the mountain (110) and the top of the valley (120) can be formed in various ways, such as curved surfaces. In addition, the part connecting the mountain (110) and the valley (120) can be formed in various ways, such as in a vertical shape parallel to the height direction.

Here, a height reduction portion (130), which is a region having a relatively lower height than the rest of the inner fin (100), may be formed on the mountain (110) or the valley (120), and the height reduction portion (130) may be formed in a portion of the mountain (110) or the valley (120) in the longitudinal direction. For example, the height reduction portion (130) may be formed in a groove shape in which a portion of the longitudinal direction of the mountain (110) or the valley (120) is pressed and concave. In addition, when the cross-section of the inner fin (100) and the tube (200) is viewed in the width direction as illustrated, the height reduction portion (130) may be formed continuously on the mountain (110) or the valley (120) in the width direction. In addition, as illustrated, the height reduction portion (130) may be formed continuously on the mountain (110) or the valley (120) along the width direction. That is, a height reduction portion (130) may be formed on all mountains (110) or on all valleys (120) in the width direction. In addition, a plurality of height reduction portions (130) formed on mountains (110) or valleys (120) along the width direction of the inner fin (100) are referred to as a height reduction portion group, and a height reduction portion group in which a height reduction portion (130) is formed on a mountain (110) among the plurality of height reduction portion groups is referred to as a first height reduction portion group (130-1), and a height reduction portion group in which a height reduction portion (130) is formed on a valley (120) among the plurality of height reduction portion groups is referred to as a second height reduction portion group (130-2), then the first height reduction portion group (130-1) and the second height reduction portion group (130-2) may be formed alternately while being spaced apart in the length direction. In a portion where there is no height reduction portion (130), all the mountains (110) and valleys (120) can come into contact with the inner surface of the tube (200). And, at a position where the height reduction portion (130) is formed in the mountain (110), the height reduction portion (130) is spaced from the inner surface of the tube (200) and the valley (120) can come into contact with the inner surface of the tube (200). In addition, at a position where the height reduction portion (130) is formed in the valley (120), the height reduction portion (130) is spaced from the inner surface of the tube (200) and the mountain (110) can come into contact with the inner surface of the tube (200).

Thus, when the inner fin (100) is inserted into the inside of the tube (200) and then joined, the mountain (110) and the valley (120) are joined by contacting the inner surface of the tube (200), and the heat exchange medium can flow longitudinally between the mountain and the valley. In addition, at a location where the height reduction portion (130), which is a region having a relatively lower height than the mountain (110) or the valley (120), is located, the heat exchange medium can flow in the width direction through the spaced space between the height reduction portion (130) and the inner surface of the tube (200). That is, a plurality of unit flow paths are connected in the width direction by the height reduction portion (130) of the inner fin (100), and the heat exchange medium between the neighboring mountains or valleys in the width direction can be communicated with each other.

Accordingly, the present invention can achieve heat exchange through convection by the widthwise flow of the heat exchange medium, so that heat exchange according to the widthwise temperature difference can be more smoothly achieved, thereby improving the heat exchange performance of the heat exchanger. In addition, in the area where the height reduction portion is not formed, the mountain or valley can be in contact with the tube and be combined, so that the tube's pressure resistance against the pressure of the heat exchange medium can be satisfied.

And since the heat exchanger of the present invention has a height reduction portion (130) formed in a mountain (110) in the B-B cross-section and a height reduction portion (130) formed in a valley (120) in the D-D cross-section, the heat exchange medium inside the tube (200) ultimately experiences both width-wise flow in the upper height direction and width-wise flow in the lower height direction. Accordingly, the heat exchange performance can be further improved. In addition, if the inner fin (100) is formed in a symmetrical shape so that the position of the height reduction portion (130) is the same as the original position when the inner fin (100) is rotated around the width-wise axis, there is no difference in performance depending on the directionality of the inner fin, and assembly and productivity can be improved.

In addition, an opening (132-1) may be formed on the longitudinal side adjacent to the height reduction portion (130). That is, the height reduction portion (130) may be formed in a form in which both longitudinal sides are cut off at a mountain (110) or a valley (120), so that the longitudinal ends of the bottom surface (131) of the height reduction portion (130) are separated from the top surface of the mountain (110) or the valley (120). Thus, the space formed by the height reduction portion (130) and the inner space of the mountain (110) or the valley (120) may be communicated with each other in the longitudinal direction. Accordingly, it is possible to prevent the flow of the heat exchange medium from stagnating in the space adjacent to both ends of the height reduction portion (130) in the longitudinal direction in which the heat exchange medium flows, and as a result, the heat exchange performance may be improved and the flow resistance of the heat exchange medium may be reduced.

In addition, the bottom surface (131) of the height reduction portion (130) may be formed as a curved surface, such as a "V" shape that is more concave than the plane as illustrated, or may be formed as a curved surface. Thus, when the height reduction portion (130) is formed through plastic deformation by pressing a mountain (110) or a valley (120), the shape of the portion adjacent to the height reduction portion (130) is prevented from being deformed or the height reduction portion (130) is prevented from being distorted, so that the shape of the height reduction portion (130) can be easily formed.

FIG. 8 and FIG. 9 are perspective views showing tubes and inner fins of a heat exchanger according to a second embodiment of the present invention, FIG. 10 is a cross-sectional view at each location of FIG. 9, and FIG. 11 is a cross-sectional view showing various embodiments of a height reduction portion in an inner fin of a heat exchanger according to a second embodiment of the present invention.

As described above, the heat exchanger according to the second embodiment of the present invention may be provided with an inner fin (100) inside a tube (200) through which a heat exchange medium flows, similar to the first embodiment described above, and the inner fin (100) may be joined to the tube (200) by brazing or the like. The inner fin (100) may be formed by bending in a corrugated shape with alternating peaks (110) and valleys (120) going in the width direction. In addition, a plurality of peaks (110) and a plurality of valleys (120) may be formed to extend in a continuous shape along the length direction. Thus, the internal space of the tube (200) may be partitioned by the peaks (110) and valleys (120) of the inner fin (100), and a plurality of unit paths through which a heat exchange medium may flow may be formed. For example, the inner fin (100) may have a height reduction portion (130) formed on the first mountain (110) in the width direction, and then another height reduction portion (130) formed every other day thereafter. Alternatively, the height reduction portion (130) may be formed on the second mountain (110) in the width direction, and then another height reduction portion (130) formed every other day thereafter. In other words, the height reduction portion may be formed on an odd-numbered mountain, or the height reduction portion may be formed on an even-numbered mountain. In addition, at a location where a height reduction portion (130) exists, the height reduction portion (130) may be formed on the first valley (120) in the width direction, and then another height reduction portion (130) formed every other day thereafter. Alternatively, the height reduction portion (130) may be formed on the second valley (120) in the width direction, and then another height reduction portion (130) formed every other day thereafter. In other words, the height reduction portion may be formed on an odd-numbered valley, or the height reduction portion may be formed on an even-numbered valley. In addition, as shown in Fig. 11, a pattern in which a height reduction portion (130) is formed on a mountain (110) and a valley (120) can be formed in various ways, and patterns of height reduction portions such as those in (a) to (e) of Fig. 11 can be arranged in a mixed manner in the longitudinal direction.

In addition, the inner fin (100) may have multiple height reduction portions (130) formed on one mountain (110) or valley (120), and the multiple height reduction portions (130) may be arranged to be spaced apart from each other in the longitudinal direction. In addition, the height reduction portions (130) may be alternately formed on the mountain or valley along the width direction. Thus, the width direction flow of the heat exchange medium may be improved, while the bonding force between the inner fin and the tube may be maintained relatively uniformly.

In addition, if a plurality of height-reducing portions (130) alternately formed on the mountain (110) or valley (120) along the width direction of the inner fin (100) are referred to as height-reducing portion groups, the height-reducing portion groups may be formed in plurality and arranged to be spaced apart from each other in the length direction. In addition, the plurality of height-reducing portion groups may be alternately formed on the mountain (110) and valley (120) along the length direction. Thus, the width direction flow of the heat exchange medium may be made smoother through the portion where the height-reducing portion of the inner fin is formed, and accordingly, the heat exchange performance improvement effect may be increased.

In addition, if a height decreasing part group in which a height decreasing part (130) is formed on a mountain (110) among a plurality of height decreasing part groups is referred to as a first height decreasing part group (130-1), the first height decreasing part groups (130-1) are formed in plurality, and the first height decreasing part groups (130-1) can be arranged to be misaligned along the longitudinal direction. That is, as illustrated, in the height decreasing parts (130) formed on the mountain (110) in the first height decreasing part group (130-1), a height decreasing part (130) can be formed every other height decreasing part (130) in the width direction. In addition, the first height decreasing part groups (130-1) that are adjacent to each other in the longitudinal direction can be arranged to be misaligned with each other in their height decreasing parts (130). Similarly, if a group of height reduction parts in which a height reduction part (130) is formed in a bone (120) among a plurality of height reduction part groups is referred to as a second group of height reduction parts (130-2), the second group of height reduction parts (130-2) is formed in plurality, and the second group of height reduction parts (130-2) can be arranged to be misaligned along the longitudinal direction. Accordingly, the widthwise flow of the heat exchange medium can be made smoother through the portion of the inner fin where the height reduction part is formed, and accordingly, the effect of improving the heat exchange performance can be increased.

In addition, the bottom surface and the sides on both sides in the longitudinal direction of the height reduction portion (130) can be formed in a blocked form. That is, the height reduction portion (130) can be formed by pressing and deforming a mountain (110) or a valley (120), and the portion where the height reduction portion (130) is formed can be in a blocked form.

Fig. 12 is a front view showing the detailed shape of a height reduction portion of an inner fin of a heat exchanger according to a second embodiment of the present invention.

As illustrated, the side surfaces (132) of the height reducing portion (130) connected to both sides in the longitudinal direction of the bottom surface (131) of the height reducing portion (130) can be connected at an acute angle with the surface forming the top of the mountain (110) or the valley (120) on which the height reducing portion (130) is formed. That is, as illustrated, the side surfaces (132) connected to both sides in the longitudinal direction of the bottom surface (131) of the height reducing portion (130) are formed with an acute angle in the side inclination angle (θ) formed with the bottom surface (131) and the surface forming the top of the mountain (110) or the valley (120), so that the height reducing portion (130) can be easily formed by pressing the mountain (110) or the valley (120), and the shape of the portion adjacent to the height reducing portion (130) can be prevented from being deformed.

Figure 13 is an assembly perspective view showing the heat exchanger of the present invention.

As described above, the heat exchanger of the present invention may include a tube (200) having an inner fin therein, and the tubes (200) may be provided in plurality. In addition, the heat exchanger of the present invention may further include a pair of header tanks (300) and a plurality of outer fins (400). The pair of header tanks (300) form a path through which a heat exchange medium is stored and flows, and may be arranged in parallel and spaced apart from each other by a predetermined distance. In addition, the header tank (300) may be formed with an inlet pipe through which the heat exchange medium is introduced and an outlet pipe through which the heat exchange medium is discharged. The tube (200) is coupled and connected to the pair of header tanks (300) to form a path through which the heat exchange medium is introduced, and the heat exchange medium may pass along the inside of the tube (200). The outer fin (400) can be interposed between the tubes (200) and joined by brazing, etc., and the outer fin (400) can play a role in increasing the heat exchange area and thus improving the heat exchange efficiency.

The present invention is not limited to the above-described embodiments, and the scope of application is diverse. Anyone with ordinary skill in the art can make various modifications without departing from the gist of the present invention as claimed in the claims.

100 : Inner pin
110 : Mountain 120 : Valley
130: Height reduction section 130-1: First height reduction section group
130-2: Second height reduction group 131: Floor surface
132 : Side θ : Side inclination angle
132-1 : Opening
200 : Tube
300 : Header Tank
400 : Outer Pin

Claims (12)

In a heat exchanger having an inner fin formed in a corrugated shape by repeating mountains and valleys inside the tube,
The inner fin is formed such that the mountains and valleys are arranged in the width direction and each extends in the length direction.
It includes a plurality of unit channels in which the internal space of the tube is divided by the mountains and valleys of the inner fin,
A heat exchanger, characterized in that at least some of the plurality of unit flow paths are connected to each other in the width direction.
In the first paragraph,
In one or more of the above mountains or valleys, an area is formed that is relatively lower in height than the height of the mountains or valleys in the remaining parts,
Areas where the height of the above mountains or valleys is relatively low are formed in some areas in the longitudinal direction,
A heat exchanger characterized in that the above-mentioned mountains and valleys are in contact with the inner surface of the tube, and an area where the height of the above-mentioned mountains or valleys is relatively low is spaced apart from the inner surface of the tube.
In the second paragraph,
A concave height reduction portion is formed on at least one of the above mountains or valleys,
A heat exchanger characterized in that the height reduction section is an area where the height of the mountain or valley is relatively low.
In the third paragraph,
Multiple height reduction zones are formed in a single mountain or valley,
A heat exchanger characterized in that the plurality of height reducing sections are arranged spaced apart from each other in the longitudinal direction.
In the third paragraph,
A heat exchanger characterized in that the height reducing portion is formed alternately in mountains or valleys along the width direction.
In the third paragraph,
If multiple height reduction areas alternately formed along the width direction in mountains or valleys are called height reduction area groups,
A heat exchanger characterized in that the above height reduction part groups are formed in multiple numbers and arranged to be spaced apart from each other in the longitudinal direction, and the multiple height reduction part groups are formed alternately in mountains and valleys along the longitudinal direction.
In Article 6,
Among the above multiple height reduction group, the height reduction group in which the height reduction part is formed on the mountain is called the first height reduction group, and among the above multiple height reduction group, the height reduction group in which the height reduction part is formed on the valley is called the second height reduction group.
The above first height reduction group is formed in plurality, and the plurality of first height reduction group are arranged in an offset manner along the longitudinal direction.
A heat exchanger characterized in that the second height reducing section group is formed in plurality, and the plurality of second height reducing section groups are arranged misaligned along the longitudinal direction.
In the third paragraph,
A heat exchanger characterized in that the height reducing portion is formed continuously in a mountain or valley along the width direction.
In the third paragraph,
A heat exchanger characterized in that the bottom surface and the side surfaces on both sides in the longitudinal direction of the above height reducing section are blocked.
In Article 9,
A heat exchanger characterized in that the side surfaces of the height reducing portion connected to both sides in the longitudinal direction of the bottom surface of the height reducing portion are connected at an acute angle to the surface forming the top of the mountain or valley on which the height reducing portion is formed.
In the third paragraph,
A heat exchanger characterized in that an opening is formed on a longitudinal side adjacent to the height reduction section.
In the first paragraph,
The above tubes are provided in multiples,
A pair of header tanks arranged spaced apart from each other and having the plurality of tubes connected thereto; and
An outer fin interposed between the plurality of tubes;
A heat exchanger further comprising:

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